Integer topological defects organize stresses driving tissue morphogenesis

Abstract Tissues acquire their function and shape via differentiation and morphogenesis. Both processes are driven by coordinating cellular forces and shapes at the tissue scale, but general principles governing this interplay remain to be discovered. Here, we report that self-organization of myoblasts around integer topological defects, namely spirals and asters, triggers localized differentiation and, when differentiation is inhibited, drives the growth of cylindrical multicellular protrusions. Both localized differentiation and growth require specific stress patterns. By analyzing the experimental velocity and orientation profiles through active gel theory, we show that integer topological defects can concentrate compressive stresses, which we measure by using deformable pillars. Altogether, we envision topological defects as mechanical organizational centers that control differentiation and morphogenesis to establish tissue architecture